Delay detector circuit and receiver apparatus

ABSTRACT

The present invention provides a delay detector circuit that delivers performance at low cost and can reduce power consumption, and a receiver apparatus that uses this delay detector circuit. The delay detector circuit according to the present invention performs a part of the decoding processing for decoding data transmitted by a transmitter apparatus based on a received wave. The receiver apparatus according to the present invention uses the delay detector circuit described above. Therefore the delay detector circuit and receiver apparatus of the present invention deliver performance at low cost and can reduce power consumption.

TECHNICAL FIELD

The present invention relates to a delay detector circuit that performsa part of decoding processing for decoding data transmitted by atransmitter apparatus based on a received wave, and a receiver apparatusthat uses the delay detector circuit.

BACKGROUND ART

Networking is progressing in various technical fields lately due to theadvancement of communication technologies, and numerous apparatuseswithin a building are connected to networks. For example, variousapparatuses including illumination, air conditioning, measurement andcrime prevention apparatuses are installed in such buildings asapartment houses, government office building, concert halls, commercialbuildings, as office buildings and private homes, and these apparatusesare interconnected via predetermined transmission lines to be networked,so it is now possible for a supervisory control apparatus connected to anetwork to perform centralized supervision and/or control (perform atleast one of centralized supervision and centralized control).

In a supervisory control system that performs centralized supervisionand/or centralized control by networking a plurality of apparatuses likethis, a communication protocol for supervisory control, fortransmitting/receiving such data as command data and supervisory data,is used. Examples of the communication protocol for supervisory controlare: communication protocols conforming to the RS485 standard, which isa typical communication protocol; LonWorks® (Local Operating Networks),which is an intelligent distributed control network technology developedby Echelon Corporation; and NMAST®, which is advocated by PanasonicElectric Works. Co., Ltd. NMAST® is characterized in that the wiringtopologies are free, and pair lines can be used for the transmissionlines.

Decoding is required in order to extract data from a communicationsignal transmitted over such a network. Examples of a decoding methodare: a synchronous detection method wherein a signal having apredetermined phase is extracted (carrier wave reproduction) from acommunication signal (receive signal) received from the network, anddecoding is performed based on this extracted signal (reference phasesignal); and a delay detection method wherein decoding is performed bycomparing phases of the received waves of adjacent symbols (time slots),that is, by regarding a value of the data as “0” (or “1”) if the phaseis the same as a signal of the previous symbol (reference signal), andregarding the value of the data as “1” (or “0”) if the phase isdifferent from this signal. In the case of the delay detection method,which performs decoding as mentioned above, it is unnecessary togenerate the reference phase signal by reproducing the carrier as in thecase of the synchronous detection method.

An example of a circuit based on this delay detection method is a delaydetector circuit disclosed in Patent Document 1. The delay detectorcircuit disclosed in Patent Document 1 comprises: a limiter amplifierthat transforms an intermediate frequency signal of a received two-phasePSK modulated wave into a rectangular wave signal, and amplifies therectangular wave; an edge detection unit which extracts only a rise edgeof the rectangular wave signal; a sawtooth wave generator that generatesa sawtooth wave signal having a cycle based on the frequency of theintermediate frequency signal; a first sample and hold circuit thatsamples and holds the sawtooth wave signal using the rise edge, anddetects a phase of the receive signal as voltage; a second sample andhold circuit that samples and holds the sampled and held signal by atiming signal of which timing is delayed by one symbol; a subtractioncircuit that detects a phase difference of adjacent two symbols bysubtracting an output signal of one of the sample and hold circuits fromthat of the other sample and hold circuit; a timing reproduction circuitthat generates a symbol timing signal synchronizing with the outputsignal of the subtraction circuit; and an identification circuit thatidentifies the output signal of the subtraction circuit, and outputs thereproduced data.

For the delay detector circuit, low cost and low power consumption aredemanded in the same way as standard circuits.

-   Patent Document 1: Japanese Patent Application Laid-Open No.    H5-183593

SUMMARY OF THE INVENTION

With the foregoing in view, it is an object of the present invention toprovide a delay detector circuit that delivers performance at low costand can reduce power consumption by using a configuration that isdifferent from the delay detector circuit disclosed in Patent Document1, and a receiver apparatus that uses this delay detector circuit.

The delay detector circuit according to the present invention performs apart of the decoding processing for decoding data transmitted by atransmitter apparatus based on a received wave. The receiver apparatusaccording to the present invention uses this delay detector circuit. Asa result, the delay detector circuit and the receiver apparatusaccording to the present invention have low cost and can reduce powerconsumption.

These and other objectives, features and advantages of the presentinvention will become more apparent upon reading the following detaileddescription along with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram depicting a communication apparatus according to anembodiment.

FIG. 2 is a diagram depicting a configuration of a receiver circuit ofthe communication apparatus shown in FIG. 1.

FIG. 3 is a diagram depicting a frame configuration of a communicationsignal used for the communication apparatus shown in FIG. 1.

FIG. 4 are diagrams depicting an operation of a tracking unit of thecommunication apparatus shown in FIG. 1.

FIG. 5 are diagrams depicting a configuration of a decoding circuit ofthe communication apparatus shown in FIG. 1.

DESCRIPTION OF EMBODIMENTS

An embodiment of the present invention will now be described withreference to the drawings. Composing elements denoted with a samereference symbol are a same composing element, for which description isomitted unless necessary.

FIG. 1 is a diagram depicting a configuration of a communicationapparatus according to an embodiment. FIG. 2 is a diagram depicting aconfiguration of a receiver apparatus of the communication apparatus ofthe embodiment. FIG. 3 is a diagram depicting a frame configuration of acommunication signal used for the communication apparatus of theembodiment. FIG. 4 are diagrams depicting an operation of a trackingcircuit of the communication apparatus of the embodiment. FIG. 5 arediagrams depicting a configuration of a decoding circuit of thecommunication apparatus of the embodiment. (A) of FIG. 5 shows a firstconfiguration of the decoding circuit, and (B) of FIG. 5 shows a secondconfiguration of the decoding circuit.

The communication apparatus M of the present embodiment is an apparatushaving: a function as a receiver apparatus that receives a communicationsignal transmitted from another communication apparatus (notillustrated) connected via a network; and a function as a transmitterapparatus that transmits a communication signal to the above mentionedother communication apparatus or still another communication apparatus(not illustrated) via the network. According to the present embodiment,a differential two-phase modulation method (DBPSK), for example, is usedfor this communication signal, and data to be transmitted is encoded(modulated) by DBPSK, whereby a transmit wave of a communication signalis generated. In the case of DBPSK, a phase change amount betweenadjacent two symbols is “0” (or “π”) if the value of the data to betransmitted is “0”, and the phase change amount is “π” (or “0”) if thevalue of the data to be transmitted is “1”.

This communication apparatus M is connected to a transmission line PLvia a bridge diode circuit 1, for example, as shown in FIG. 1, andcomprises a power receiving unit 2, an analog front end unit (AFE unit)3, a communication unit 4, and an input/output interface circuit(input/output IF unit) 5.

The transmission line PL is a medium for propagating (transmitting) acommunication signal, and is connected to the network, or constitutes apart of the network. The transmission line PL is a pair of lines, forexample, according to the present embodiment. In the present embodiment,the communication apparatus M is connected to the pair of lines via thebridge diode circuit 1, as mentioned above, hence the wiring polarityupon connecting the communication apparatus M to the pair lines isnon-polar, and the communication apparatus M can be connected to thepair lines without concern for the polarity of the pair lines. In otherwords, one terminal and the other terminal of a pair of input ends ofthe bridge diode circuit 1 can either be connected to a voltage line anda ground line of the pair lines respectively, or connected to a groundline and a voltage line of the pair lines respectively.

The power receiving unit 2 is a circuit that is connected to the bridgediode circuit 1, and generates drive power for driving thiscommunication apparatus M from the power that flows over thetransmission line PL via the bridge diode circuit 1. According to thepresent embodiment, the power receiving unit 2 comprises an impedanceupper circuit 21 which becomes high impedance with respect to thecommunication band of the communication signal that propagates over thetransmission line PL, and a power supply circuit 22 that generates DCpower from AC power. “High impedance with respect to the communicationband” means that the communication signal propagating over thetransmission line PL has little influence on the transmission distance.The impedance circuit 21 comprises an inductor which becomes highimpedance with respect to the communication band of the communicationsignal that propagates over the transmission lines PL, for example. Thepower supply circuit 22 comprises a three-terminal regulator and acapacitor, and generates a drive power having a predetermined constantvoltage from AC power.

The power flowing over the transmission line PL is supplied to the powerreceiving unit 2 via the bridge diode circuit 1. The power receivingunit 2 converts the power supplied via the impedance upper circuit 21into the drive power having a predetermined constant voltage by thepower supply circuit 22, and supplies the predetermined constant voltageto each unit of the communication apparatus M, such as the AFE unit 3and the communication unit 4, that requires drive power.

The AFE unit 3 is a circuit that is connected to the bridge diodecircuit 1, and connects the transmission line PL and the communicationunit 4 via the bridge diode circuit 1, and the AFE unit 3 extracts areceived wave, namely, a communication signal from the transmission linePL, and outputs the received wave to the communication unit 4, andtransmits a transmitted wave, namely, a communication signal from thecommunication unit 4 to the transmission lines PL via the bridge diodecircuit 1. According to the present embodiment, the AFE unit 3 comprisescapacitors C1 and C2, an amplifier 31 and a limiter amplifier 32, forexample. The capacitors C1 and C2 are elements that cut off thefrequency of the power component that flows over the transmission linePL, in other words, the frequency of the power components other than atleast the power components of the communication signal. One terminal ofthe capacitor C1 is connected to the output terminal of the amplifier31, and the other terminal of the capacitor C1 is connected to thevoltage line of the bridge diode circuit 1, whereby the capacitor C1 isdisposed between the amplifier 31 and the bridge diode circuit 1. Oneterminal of the capacitor C2 is connected to the voltage line of thebridge diode circuit 1, and the other terminal of the capacitor C2 isconnected to the input terminal of the amplifier 32 which is describedlater, whereby the capacitor C2 is disposed between the bridge diodecircuit 1 and the amplifier 32. The amplifier 31 is a circuit thatamplifies a communication signal inputted from the communication unit 4,at a predetermined amplification factor, and the drive power suppliedfrom the power receiving unit 2 is used for driving.

The limiter amplifier 32 is a circuit that transforms the received wave,received from the transmission line PL via the bridge diode circuit 1and the capacitor C2, into a rectangular wave signal which has anapproximately rectangular waveform, by limiting the amplitude of thereceived wave with a predetermined constant value, and amplifies therectangular wave signal. The output characteristic of the limiteramplifier 32 has hysteresis, and if a predetermined threshold or highervoltage value is input, the limiter amplifier 32 outputs a predeterminedhigh level voltage value, and if a voltage value less than thepredetermined threshold is input, the limiter amplifier 32 outputs apredetermined low level target value. The limiter amplifier 32 is drivenby the drive power supplied from the power receiving unit 2 to theamplifier 32.

A communication wave, detected as to a communication signal propagatingover the transmission line PL, is received as a received wave via thebridge diode circuit 1, and this received wave is inputted to thelimiter amplifier 32 via the capacitor C2 of the AFE unit 3, istransformed into a rectangular wave signal according to the amplitudelevel of the received wave, and is amplified. The amplified rectangularwave signal, generated from the received wave, is output from thelimiter amplifier 32 of the AFE unit 3 to the communication unit 4. Thecommunication signal generated by the communication unit 4 is inputtedfrom the communication unit 4 to the amplifier 31 of the AFE unit 3, isamplified at a predetermined amplification factor, and is transmitted tothe transmission line PL via the capacitor C1 and the bridge diodecircuit 1.

According to the present embodiment, the limiter amplifier 32 may be anactive filter having a function of a bandpass filter (BPF), whichextracts only the communication band (transmission band) used for thecommunication. Thereby signals having a frequency other than the abovementioned transmission band can be removed as noise.

The communication unit 4 is a circuit that is connected to the powerreceiving unit 2 and the AFE unit 3 respectively, and decodes(demodulates) data of a communication signal based on a rectangular wavesignal inputted from the limiter amplifier 32 of the AFE unit 3, andalso encodes (modulates) data to be transmitted as a communicationsignal. According to the present embodiment, the communication unit 4comprises a transmitter circuit 41 that encodes (modulates) the data tobe transmitted as a communication signal, and a receiver circuit 42 thatdecodes (demodulates) the data of the communication signal based on theoutput of the limiter amplifier 32 of the AFE unit 3. Details on thereceiver circuit 42 are described later.

The input/output IF unit 5 is an interface circuit that is connected tothe communication unit 4, so that data can be inputted/outputted betweenthis communication apparatus M and an external apparatus. When theexternal apparatus is connected to the input/output IF unit 5, the datainputted from the external apparatus to the input/output IF unit 5 isoutputted to the transmitter circuit 41 of the communication unit 4, andencoded (modulated) by the transmitter circuit 41 of the communicationunit 4, and data decoded (demodulated) by the receiver circuit 42 of thecommunication unit 4, on the other hand, is outputted to theinput/output IF unit 5, and is outputted to the external apparatus.

As FIG. 2 shows, the receiver circuit 42 comprises a delay detectorcircuit S, a tracking circuit 8 and a decoding circuit 9, for example.

The delay detector circuit S is a circuit that is connected to theoutput terminal of the limiter amplifier 32 of the AFE unit 3, so thatthe output of the limiter amplifier 32 is inputted, and detects whethera received wave is a communication signal. More specifically, the delaydetector circuit S comprises: a delay correlation operation circuit 6that performs the delay correlation operation on the received wave; anacquisition circuit 7 that detects whether the received wave is acommunication signal transmitted by the other communication apparatusbased on the output of the delay correlation operation circuit 6; and anoutput unit SL that outputs the output of the delay correlationoperation circuit 6 to the decoding circuit 9 that decodes data based onthe output of the delay correlation operation circuit 6. According tothe present embodiment, the acquisition circuit 7 operates first andacquires a communication signal transmitted by the other transmitterapparatus based on the output of the delay correlation operation circuit6. Then the later mentioned decoding circuit 9 operates and detects thelater mentioned end of the preamble unit.

According to the present embodiment, the output unit SL has wiring thatconnects the delay correlation operation circuit 6 and the decodingcircuit 9 (e.g. including a lead line, a wiring pattern on a board, anda wiring pattern on an integrated circuit). The output unit SL is notlimited to this wiring, but may be a terminal for outputting the outputof the delay correlation operation circuit 6, for example.

The delay correlation operation circuit 6 is connected to the limiteramplifier 32 of the AFE unit 3, and comprises an I multiplier (I mixer)61I, an I Nyquist filter 62I, an I shift register 63I, an I correlationoperation circuit 64I, a Q multiplier (Q mixer) 61Q, a Q Nyquist filter62Q, a Q shift register 63Q, a Q correlation operation circuit 64Q, andan adder 65, for example. The output of the limiter amplifier 32 of theAFE unit 3 is sampled at a predetermined sampling interval, is input tothe receiver circuit 42, and is input to the delay correlation operationcircuit 6. The sampling interval is determined by a so called samplingtheorem, but in the present embodiment, the setup is such that awaveform of one symbol is sampled at a predetermined n number ofsampling points, which are set in advance.

The I multiplier 61I is a circuit that is connected to the limiteramplifier 32 of the AFE unit 3, and generates an I signal component bymultiplying the output of the limiter amplifier 32 by sin ωt of thelocal frequency ω. The I Nyquist filter 62I is a circuit that isconnected to the I multiplier 61I, and filters the I signal componentoutputted from the I multiplier 61I using a predetermined Nyquist filtercharacteristic. The Nyquist filter for reception is configured so as tohave the Nyquist characteristic as a set with the Nyquist filter fortransmission. The I shift register 63I is a circuit that is connected tothe I Nyquist filter 62I, and stores the output of the I Nyquist filter62I as a predetermined number of bits of data. In the presentembodiment, the receiver circuit 42 is configured in such a way that awaveform of one symbol is sampled at n number of sampling points, hencethe I shift register 63I is constituted by n bits, so that data for onesymbol can be stored. The shift register is a digital circuit in which aplurality of flip-flops, each of which stores 1-bit data (value), arecascade-connected, and 1-bit data is sequentially shifted within thecircuit. The I correlation operation circuit 64I is a circuit that isconnected to the I Nyquist filter 62I and the I shift register 63I, andperforms the correlation operation between the output of the I Nyquistfilter 62I and the output of the I shift register 63I. Thereby the delaycorrelation operation is performed for the I signal component.

In the same manner, the Q multiplier 61Q is a circuit that is connectedto the limiter amplifier 32 of the AFE unit 3, and generates a Q signalcomponent by multiplying the output of the limiter amplifier 32 by −cosωt of the local frequency ω. The Q Nyquist filter 62Q is a circuit thatis connected to the Q multiplier 61Q, and filters the Q signal componentoutputted from the Q multiplier 61Q using a predetermined Nyquist filtercharacteristic. The Nyquist filter for reception is configured so as tohave the Nyquist characteristic as set with the Nyquist filter fortransmission. The Q shift register 63Q is a circuit that is connected tothe Q Nyquist filter 62Q, and stores the output of the Q Nyquist filter62Q as a predetermined number of bits of data. The Q shift register 63Qis constituted by n bits so that data for one symbol can be stored. TheQ correlation operation circuit 64Q is a circuit that is connected tothe Q Nyquist filter 62Q and the Q shift register 63Q, and performscorrelation operation between the output of the Q Nyquist filter 62Q andthe output of the Q shift register 63Q. Thereby the delay correlationoperation is performed for the Q signal component.

The adder 65 is a circuit that is connected to the I correlationoperation circuit 64I and the Q correlation operation circuit 64Qrespectively, and adds the output of the I correlation operation circuit64I and the output of the Q correlation operation circuit 64Q. Theresult of this addition is output to the acquisition circuit 7 and thedecoding circuit 9 respectively by the output unit SL as the output ofthe delay correlation operation circuit 6.

This acquisition circuit 7 is connected to the delay correlationoperation circuit 6, and comprises a square operation circuit 71, afirst threshold comparison circuit 72, a shift register for sync 73, acandidate comparison circuit 74, a conformity determination circuit 75,and a pattern candidate storage circuit 76, for example, as shown inFIG. 2.

The square operation circuit 71 is a circuit that is connected to theadder 65 of the delay correlation operation circuit 6, and computes asquare of the output of the delay correlation operation circuit 6, thatis the output of the adder 65. The first threshold comparison circuit 72is a circuit that is connected to the square operation circuit 71, andbinarizes the output of the square operation circuit 71 by comparing theoutput of the square operation circuit 72 (square result) and apredetermined first threshold Th1, which is set in advance. The shiftregister for sync 73 is a circuit that is connected to the firstthreshold comparison circuit 72, and stores the output of the firstthreshold comparison circuit 72 (first threshold comparison result) as apredetermined number of bits of data. The shift register for sync 73 isconstituted by n bits, so that data for one symbol can be stored.

The output of the delay correlation operation circuit 6 is squared bythe square operation circuit 71, the square result is compared with thepredetermined first threshold Th1 by the first threshold comparisoncircuit 72, and the first threshold comparison result is stored in theshift register for sync 73. Thereby a shape of one symbol is generatedbased on the output of the delay correlation operation circuit 6, andthe shape of one symbol based on the delay correlation operation circuit6 is stored in the shift register for sync. Thus the shape of one symbolis represented by a plurality of bits. The square operation circuit 71,the first threshold comparison circuit 72 and the shift register forsync 73 constitute a shape generation unit that generates a shape of onesymbol based on the output of the delay correlation operation circuit 6,and correspond to examples of the shape generation unit.

The pattern candidate storage circuit 76 is a circuit that stores inadvance a plurality of candidates of the shape of one symbol as apattern candidate. The pattern candidate has a predetermined bit patternformed by predetermining a value of each bit, and the plurality ofpattern candidates has mutually different bit patterns, and in at leastone of the plurality of pattern candidates, at least one bit has anarbitrary value.

The frame 100 of the communication signal has a preamble portion 101 anda payload portion 102 for storing data to be transmitted, for example,as shown in FIG. 3, and the preamble portion 101 has: a synchronizationpattern unit 111 that stores a synchronization pattern used forsynchronizing the decoding timing with the received wave in order todecode the data from the received wave; and an SFD unit 112 whichirradiates the end of the synchronization pattern unit 111. The SFD unit112 indicates the end of the preamble portion 101, and also indicatesthe start of the payload portion 102.

According to the present embodiment, “111 . . . 111”, for example, isstored in the synchronization pattern unit 111 as a synchronizationpattern, and “1010”, for example, is stored in the SFD unit 112. InDBPSK, a phase change amount between two adjacent symbols and a value ofdata are corresponded, as mentioned above. In the case of DBPSK, if 111. . . 111 is set, the phase inverts each time, therefore “111 . . . 111”is used for the synchronization pattern so as to perform synchronizationeasily.

In the case of sampling one symbol at n number of sampling points, ifthe result of the delay correlation operation is squared and if thesquared result is compared with the first threshold, then the result is“1” near the center of 16 sampling points, and is “0” in the rest of thearea if the received wave barely has noise (noise is barely superposedon the received wave), that is, “00 . . . 01110 . . . 00”, or 00 . . .00100 . . . 00”, for example. However, if noise is superposed on thereceived wave, or if the phase is shifted, “1” may appear in a place notnear the center of the n number of sampling points in the firstthreshold determination result. Therefore according to the presentembodiment, a plurality of pattern candidates is stored in the patterncandidate storage circuit 76, and the plurality of pattern candidatesincludes a pattern that has “1” in a place not near the center of the nsampling points, and a pattern in which a place not near the center ofthe n sampling points is not defined (data value is arbitrary, that is,the data value can be either “0” or “1”). The plurality of patterncandidates are predetermined considering the topology of thetransmission line used by this communication apparatus and thetransmission characteristic thereof (e.g. determines how phases aredistorted), for example, and not only the two patterns “00 . . . 01110 .. . 00” and “00 . . . 00100 . . . 00”, but also such patterns as “00 . .. 011110 . . . 00” and “00 . . . 1XX1111XXX1 . . . 00” are included. “X”indicates either “0” or “1”. Thus the pattern candidates are bitpatterns generated by predetermining a value of each bit, and theplurality of pattern candidates has mutually different bit patterns, andin at least one of the plurality of pattern candidates, at least one ofthe bits has an arbitrary value.

The candidate comparison circuit 74 is a circuit that is connected tothe shift register for sync 73 and the pattern candidate storage circuit76 respectively, and compares a shape of one symbol stored in the shiftregister for sync 73 and each shape of a plurality of pattern candidatesstored in the pattern candidate storage circuit 76. Upon comparing theshape of one symbol stored in the shift register for sync 73 and eachshape of the plurality of pattern candidates stored in the patterncandidate storage circuit 76, the candidate comparison circuit 74compares each value stored in each bit of the shift register for sync 73and each value of each bit of a pattern candidate.

The conformity determination circuit 75 is a circuit that is connectedto the candidate comparison circuit 74, and regards the received wave asa communication signal transmitted by another communication apparatus ifthe shape of one symbol of the shift register for sync 73 and any one ofthe plurality of pattern candidates match for a plurality of times withan n sample interval (one symbol interval) as a result of comparison bythe candidate comparison circuit 74 that is input by the candidatecomparison circuit 74. The number of matches can be two, three or fourtimes, for example. The determination accuracy improves as the number ofmatches increases, but the determination time becomes lengthy.

The tracking circuit 8 is a circuit that is connected to the delaydetector circuit S, and adjusts the time interval corresponding to thelength of one symbol when a predetermined processing is performed withthe time interval, so that decoding can be performed at a center timeposition in one symbol. In the present embodiment, the predeterminedprocessing is the decoding processing by the data decoding circuit 92for the shift register for dec 91 of the decoding circuit 9. Morespecifically, the tracking circuit 8 comprises a shift register for Tr81 and an interval adjustment circuit 82, for example, as shown in FIG.2.

The shift register for Tr 81 is a circuit that is connected to thesquare operation circuit 71 of the delay detector circuit S, and storesthe squared result generated by squaring one symbol of the output of thedelay correlation operation circuit 6 by the square operation circuit71. The internal adjustment circuit 82 is a circuit that is connected tothe shift register for Tr 81, compares, in the square result for onesymbol stored in the shift register for Tr 81, a sampling value (meanvalue) at a center position located approximately at the center, asampling value (early value) located at a preceding time position, whichis one sampling before the center time position, and a sampling value(late value) located at a subsequent time point, which is one samplingafter the center time point, and adjusts the time interval according tothe comparison result. More specifically, the mean value, the earlyvalue and the late value are compared at every n cycle, and one point isadded to the counter indicating the highest value in the comparisonresult, out of a MEAN counter, an EARLY counter and a LATE counter,which correspond to the mean value, the early value and the late valuerespectively. If the value of the MEAN counter exceeds the predeterminedsecond threshold Th2, the time adjustment circuit 82 operates thedecoding circuit 9 so that the current time interval is maintained. Ifthe value of the EARLY counter exceeds the predetermined secondthreshold Th2, the time adjustment circuit 82 operates the decodingcircuit 9 so that the current time interval increases by one samplelength. If the value of the LATE counter exceeds the predeterminedsecond threshold Th2, the time adjustment circuit 82 operates thedecoding circuit 9 so that the current time interval decreases by onesample length.

According to the present embodiment, each circuit operates according tothe clock timing of the operation clock, and one symbol is sampled at nnumber of sampling points, so if the value of the MEAN counter exceedsthe predetermined second threshold Th2, as shown in FIG. 4, this meansthat the approximately center time position of the symbol and the timingfor the decoding circuit 9 to decode the data match (see (I) of FIG. 4),therefore the time adjustment circuit 82 operates the decoding circuit 9at an n cycle interval (see (A), (B), (C) and (E) of FIG. 4), so as tomaintain the current synchronization timing. If the value of the EARLYcounter exceeds the predetermined second threshold Th2, this means thatthe timing for the decoding circuit 9 to decode data is before theapproximately center time position of the symbol (see (I) of FIG. 4),therefore the time adjustment circuit 82 outputs an early_out signal soas to delay the current synchronization timing, whereby the decodingcircuit 9 is operated at an (n+1) cycle interval only once (see (A),(B), (C), (D) and (G) of FIG. 4). If the value of the LATE counterexceeds the predetermined second threshold Th2, this means that thetiming for the decoding circuit 9 to decode data is after theappropriate center time position of the symbol (see (I) of FIG. 4),therefore the time adjustment circuit 82 outputs a late_out signal so asto advance the current synchronization timing, whereby the decodingcircuit 9 is operated at an (n−1) cycle interval only once (see (A),(B), (C), (F) and (H) of FIG. 4).

(A) of FIG. 4 shows a clock for synchronizing operation timing of eachcircuit of the communication unit 4, (B) of FIG. 4 shows each bit value(correlation signal) of the shift register for Tr 81, (C) of FIG. 4shows a synchronization timing established by the delay detector circuitS, (D) of FIG. 4 shows the EARLY counter, (E) of FIG. 4 shows the MEANcounter, (F) of FIG. 4 shows the LATE counter, (G) of FIG. 4 shows theearly_out signal, (H) of FIG. 4 shows the late_out signal, and (I) ofFIG. 4 is a partially enlarged view of (B) of FIG. 4 and (C) of FIG. 4.

The decoding circuit 9 is a circuit that is connected to the delaycorrelation operation circuit 6 of the delay detector circuit S via theoutput unit SL, and decodes data based on the output of the delaycorrelation operation circuit 6. More specifically, the decoding circuit9 comprises a shift register for Dec 91 and a data decoding circuit 92,for example, as shown in FIG. 2 ((A) of FIG. 5).

The shift register for Dec 91 is a circuit that is connected to thedelay correlation operation circuit 6 of the delay detector circuit Svia the output unit SL, and stores the output of the delay correlationoperation circuit 6 for one symbol. The data decoding circuit 92 is acircuit that is connected to the shift register for Dec 91, and decodesdata based on the value at a center position located approximately atthe center of the shift register for Dec 91. More specifically, thecommunication signal is encoded by DBPSK, hence the data decodingcircuit 92 generates the decoded data by corresponding the sign bit ofthe value at the center position (bit at the center position) locatedapproximately at the center of the shift register for Dec 91 to “1” or“0”.

The decoding circuit 9 may have a configuration shown in (B) of FIG. 5instead of the configuration shown in FIG. 2 ((A) of FIG. 5). In otherwords, as (B) of FIG. 5 shows, the decoding circuit 9A comprises a shiftregister for Dec 91 and a data decoding circuit 92A. The shift registerfor Dec 91 is a circuit that is connected to the delay correlationoperation circuit 6 if the delay detector circuit S via the output unitSL, and stores an output of the delay correlation operation circuit 6for one symbol. The data decoding circuit 92A is a circuit that isconnected to the shift register for Dec 91, and decodes data based on avalue at a center position located approximately at the center of theshift register for Dec 91, and a value at a preceding time position thatprecedes the center position, and a value at a subsequent time positionthat is subsequent to the center position (each value of a predeterminednumber of bits (1 or a plurality of bits) located immediately before andimmediately after the center position). More specifically, thecommunication signal is encoded by DBPSK, hence the data decodingcircuit 92A generates the decoded data by corresponding the sign bit ofthe sum of the value at the center position located approximately at thecenter of the shift register for Dec 91 (value of a bit at the centerposition), the value at the preceding time position preceding the centerposition, and the value at the subsequent time position subsequent tothe center position (e.g. each value of a predetermined number of bits(1 or a plurality of bits) located immediately before and immediatelyafter the center position) to “1” or “0”. The number of bits before andafter the center position is 3 bits before and 3 bits after the centerposition in the example shown in (B) of FIG. 5, but the presentembodiment is not limited to this, and may be 2 bits before and 2 bitsafter the center position, or 1 bit before and 1 bit after the centerposition. Thus according to the decoding circuit 9A having theconfiguration shown in (B) in FIG. 5, not only a value at the centerposition located roughly at the center of the shift register for Dec 91,but also a value at a preceding position of the center position and avalue at a subsequent position of the center position, such as thevalues located immediately before and immediately after the centerposition, are used for decoding data, therefore the data can be decodedmore accurately at a higher precision.

The receive operation of the communication apparatus M of the presentembodiment will now be described. When the communication apparatus M ofthe present embodiment starts operation by turning a power supply switch(not illustrated) ON and starts the receive operation for receiving acommunication signal, the communication apparatus M loads a receivedwave from the transmission line PL to the AFE unit 3 via the bridgediode circuit 1, regardless whether a communication signal exists. Theloaded received wave is input to the limiter amplifier 32 via thecapacitor C2, and is transformed into a waveform according to theamplitude level of the received wave by the limiter amplifier 32, andthe waveform-transformed received wave is output from the limiteramplifier 32 to the receiver circuit 42 of the communication unit 4.

In the receiver circuit 42, delay detector circuit S performs the delaydetection. More specifically, the waveform-transformed received wave isinput to the I multiplier 61I and the Q multiplier 61Q respectively.

In the I multiplier 61I, the waveform-transformed received wave ismultiplied by the sin ωt, and the I signal component generated by thismultiplication is input to the I Nyquist filter 62I. In the I Nyquistfilter, the I signal component is filtered by the filter characteristicof the Nyquist filter, which is implemented by a set of the Nyquistfilter for reception and the Nyquist filter for transmission, and thefiltered I signal component is input to the I shift register 63I and theI correlation operation circuit 64I. In the I shift register 63I, thefiltered I signal component sequentially shifts from the bit (flip-flop)of the input terminal to the bit (flip-flop) of the output terminalaccording to the clock timing of the operation clock, and is input tothe I correlation operation circuit 64I. In the I correlation operationcircuit 64I, correlation operation (multiplication) is performed on thefiltered I signal component inputted from the I Nyquist filter 62I andthe filtered I signal component one symbol ago, which was inputted fromthe I shift register 63I according to the clock timing of the operationclock, and the result of the correlation operation is input to the adder65.

In the same manner, in the Q multiplier 61Q, the waveform-transformedreceived wave is multiplexed by the −cos ωt, and the Q signal componentgenerated by this multiplication is input to the Q Nyquist filter 62Q.In the Q Nyquist filter, the Q signal component is filtered by thefilter characteristic of the Nyquist filter, which is implemented by aset of the Nyquist filter for reception and the Nyquist filter fortransmission, and the filtered Q signal component is input to the Qshift register 63Q and the Q correlation operation circuit 64Q. In the Qshift register 63Q, the filtered Q signal component sequentially shiftsfrom the bit (flip-flop) of the input terminal to the bit (flip-flop) ofthe output terminal according to the clock timing of the operationclock, and is input to the Q correlation operation circuit 64Q. In the Qcorrelation operation circuit 64Q, correlation operation(multiplication) is performed on the filtered Q signal componentinputted from the Q Nyquist filter 62Q and the filtered Q signalcomponent one symbol ago, which was inputted from the Q shift register63Q according to the clock timing of the operation clock, and the resultof the correlation operation is input to the adder 65.

The result of the correlation operation of the I correlation operationcircuit 64I and the result of the correlation operation of the Qcorrelation operation circuit 64Q are added in the adder 65, and thisaddition result is outputted to the output unit SL, and is inputted tothe acquisition circuit 7 and the decoding circuit 9 respectively.

Here if the receive wave is S(i), the real part of the received weaveS(i) is I(i), the imaginary part of the received wave S(i) is Q(i) andthe imaginary unit is j(j²=−1), then the received wave S(i) is given byS(i)=I(i)+jQ(i), and the received wave S(i−T) one symbol ago is given byS(i−T)=I(i−T)+jQ(i−T). The time T is a time length of one symbol.According to the communication apparatus M of the present embodiment, awaveform of one symbol is sampled at n number of sampling points,therefore T=n×sampling interval. i is a clock number of the operationclock. Under these definitions, the delay correlation value c(i) isgiven byc(i)=(I(i)+jQ(i))·(I(i−T)·jQ(i−T))=[I(i)I(i−T)+Q(i)Q(i−T)]+j[Q(i)I(i−T)−I(i)Q(i−T)]=A+jB,A=I(i)I(i−T)+Q(i)Q(i−T), B=Q(i)I(i−T)−I(i)Q(i−T). According to thecommunication apparatus M of the present embodiment, which is based onDBPSK, the above mentioned operation is performed by the above mentionedconfiguration, ignoring the imaginary part B, and only the real part Ais used for the decoding circuit.

In the acquisition circuit 7, the addition result (delay correlationvalue c(i)=A) inputted from the delay correlation operation circuit 6 tothe acquisition circuit 7 is inputted to the square operation circuit 71first. In the square operation circuit 71, the delay correlation value Ais squared, and this square result (e(i)=A²=((I(i)I(i−T))+(Q(i)Q(i−T))²is inputted to the first threshold comparison circuit 72. In the firstthreshold comparison circuit 72, this square result A² is compared withthe predetermined first threshold Th1 and binarized, and this binarizedsquare result A²′ is inputted to the shift register for sync 73. Inother words, if the square result A² is smaller than the predeterminedfirst threshold Th1, “0” is input, and if the square result A² is thepredetermined first threshold Th1 or greater, “1” is input. In the shiftregister for sync 73, this binarized square result A²′ sequentiallyshifts from the bit (flip-flop) of the input terminal to the bit(flip-flop) of the output terminal according to the clock timing of theoperation clock. The candidate comparison circuit 74 compares the shapeof one symbol in the shift register for sync 73 and a shape of each ofthe plurality of pattern candidates in the pattern candidate storagecircuit 76 at each clock timing of the operation clock, and thecomparison result is input to the conformity determination circuit 75.This comparison is executed by comparing corresponding bits. In theconformity determination circuit 75, a number of times when the shape ofone symbol in the shift register for sync 73 and any one of theplurality of pattern candidates in the pattern candidate storage circuit76 match in the comparison by the candidate comparison circuit 74 iscounted based on the comparison result.

By each bit of the synchronization pattern that is receivedsuccessively, the matched comparison result is input from the candidatecomparison circuit 74 to the conformity determination circuit 75 in thereceiver circuit 42, and the number of times of the match is counted upin the conformity determination circuit 75 based on the comparisonresult. According to the present embodiment, one symbol is sampled at nnumber of sampling points, therefore if the first match is determined,the acquisition circuit 7 judges the second match at each point of (n−1)sampling points after the determination of the first match, n samplingpoints after the determination of the first match, and (n+1) samplingpoints after the first determination of match, in order to perform thejudgment efficiently. The acquisition circuit 7 may be configured sothat the judgment of match is performed n sampling pints after thedetermination of the first match, but a more accurate synchronizationpattern can be acquired if the judgment is performed not only n samplingpoints later, but also (n−1) sampling points later and (n+1) samplingpoints later, which are the timings before and after the n samplingpoints, as mentioned above. Furthermore according to the presentembodiment, if the second match is determined, the acquisition circuit 7judges the third match at each point of (2n−2) sampling points after thedetermination of the first match, (2n−1) sampling points after thedetermination of the first match, 2n sampling points after thedetermination of the first match, (2n+1) sampling points after thedetermination of the first match, and (2n+2) sampling points after thedetermination of the first match. The acquisition circuit 7 may beconfigured so that the judgment of match is performed 2n sampling pointsafter the determination of the first match, or (n−1) sampling after, nsampling after and (n+1) sampling after the determination of the secondmatch.

If the number of times of match becomes three, it is regarded as thedetection of the preamble portion 101, and synchronization is acquiredbased on the delayed detection. After this synchronization acquisition,the conformity determination circuit 75 of the acquisition circuit 7allows the tracking circuit 8 to start the tracking operation, andallows the decoding circuit 9 to start the decoding operation.

When the tracking operation is started in the tracking circuit 8, thesquare result (e(i)=A²), inputted from the square operation circuit 71of the acquisition circuit 7, sequentially shifts from the bit(flip-flop) of the input terminal to the bit (flip-flop) of the outputterminal in the shift register for Tr 81, according to the clock timingof the operation clock. According to the synchronization acquired by thedelay detector circuit S, the time adjustment circuit 82 compares asampling value (mean value) at a center position located approximatelyat the center of the shift register for Tr 81, a sampling value (earlyvalue) at a preceding time position that is one sampling point beforethe center position, and a sampling value (late value) at a subsequenttime position that is one sampling point after the center position, andadjusts the time interval according to the comparison result. Morespecifically, as described with reference to FIG. 4, if the value of theMEAN counter exceeds the predetermined second threshold Th2, theinterval adjustment circuit 82 operates the decoding circuit 9 with ncycles as the time interval, so that the current synchronization timingis maintained. If the value of the EARLY counter exceeds thepredetermined second threshold Th2, the interval adjustment circuit 82operates the decoding circuit 9 with the (n+1) cycle as the timeinterval only once, so as to delay the current synchronization timing.If the LATE counter exceeds the second threshold Th2, the intervaladjustment circuit 82 operates the decoding circuit 9 with the (n−1)cycle as the time interval only once, so as to advance the currentsynchronization timing.

When the decoding operation is started in the decoding circuit 9, thedelay correlation value c(i) (=A), inputted from the delay correlationoperation circuit 6 of the delay detector circuit S, sequentially shiftsfrom the bit (flip-flop) of the input terminal to the bit (flip-flop) ofthe output terminal in the shift register for Dec 91, according to theclock timing of the operation clock. The data decoding circuit 92corresponds the sign bit of the value at the center position (bit at thecenter position) located approximately at the center of the shiftregister for Dec 91 to “0” or “1” as the decoding data, according to thesynchronization acquired by the delay detector circuit S.

In the case of using the data decoding circuit shown in (B) of FIG. 5,instead of the data decoding circuit 92, the data decoding circuit 92Acorresponds the sign bit of the sum of the value at the center positionlocated approximately at the center of the shift register for Dec 91(value of the bit at the center position) and each value locatedimmediately before and after the center position (each value of each bitbefore and after the bit at the center position) to “0” or “1” as thedecoding data, according to the synchronization established by the delaydetector circuit S.

Then the acquisition circuit 7 checks the data decoded like this by thedecoding circuit 9 after the synchronization acquisition, and detectsthe end of the preamble portion 101 by detecting the bit pattern of theSFD unit 112 of the preamble portion 101, such as the above mentioned“1010”, whereby synchronization with the transmit signal is established.

By this operation, if a communication signal propagates through thetransmission line PL, the communication apparatus M can perform delaydetection on the communication signal, and decode data from thecommunication signal.

In the communication apparatus M and the delay detector circuit S of thepresent embodiment, delay detection is performed by the delaycorrelation operation circuit 6 performing the delay correlationoperation on a received wave, and the acquisition circuit 7 determineswhether this received wave is a communication signal transmitted by thetransmitter apparatus based on the output of the delay correlationoperation circuit 6. Then the result of the delay correlation operation(delay correlation value c(i) (=A)) generated during the delay detectionprocessing is output to the decoding circuit 9 via the output unit SL.Comparing with a typical receiver apparatus, which divides the receivedwave into two and performs delay detection using one of the receivedwaves and performs decoding using the other received wave, thecommunication apparatus M and the delay detector circuit S of thepresent embodiment, where a part of the delay detector circuit is usedfor the decoding processing, have low cost and can reduce powerconsumption.

In the communication apparatus M and the delay detector circuit S of thepresent embodiment, a plurality of candidates of a shape of one symbol(pattern candidates) is provided, and the plurality of patterncandidates is stored in the pattern candidate storage circuit 76 inadvance. Therefore it is easier to determine whether the received waveis a communication signal transmitted by another communicationapparatus, and the communication apparatus M and the delay detectorcircuit S of the present embodiment can acquire the received wave withcertainty. On the other hand, if a shape of one symbol in the shiftregister for sync 73 and any one of the plurality of pattern candidatesmatch a plurality of times, the communication apparatus M and the delaydetector circuit S of the present embodiment regard this received waveas a communication signal transmitted by another communication apparatus(synchronization acquisition). Therefore the communication apparatus Mand the delay detector circuit S of the present embodiment can determinethat this received wave is a communication signal transmitted by anothercommunication apparatus, and accurately perform delay detection.

According to the communication apparatus M and the delay detectorcircuit S of the present embodiment, in at least one of the plurality ofpattern candidates, at least one of the bits has an arbitrary value.Therefore even if the shape of the symbol becomes different from thewaveform transmitted by another communication apparatus duringtransmission, this received wave can be determined as the communicationsignal transmitted by the other communication apparatus, and thecommunication apparatus M and the delay detector circuit S of thepresent embodiment can acquire the received wave with certainty.

The communication apparatus M and the delay detector circuit S of thepresent embodiment can correct the shift of the clock interval ofanother communication apparatus and the clock interval of thecommunication apparatus M since the tracking circuit 8 is included, andthe delay detection can be performed with certainty.

The communication apparatus M and the delay detector circuit S of thepresent embodiment can decode data based on the received wave, since thedecoding circuit 9 is included.

In the case of a typical conventional means, an auto gain controlamplifier (AGC amplifier) and an analog-digital converter (AD convertor)are used for the circuit before the input of the receiver circuit, andthe received wave loaded from the transmission line PL is adjusted tohave an appropriate amplitude by the AGC amplifier, is converted fromthe analog signal to the digital signal by the AD converter, and isinput to the receiver circuit. In the case of the communicationapparatus M of the present embodiment, on the other hand, the limiteramplifier 32 is used for the circuit before the input of the receivercircuit 42, as mentioned above, and the received wave loaded from thetransmission line PL is transformed into a rectangular wave signal bythe limiter amplifier 32, and is inputted to the receiver circuit 42.Thus in the case of the communication apparatus M of the presentembodiment using the limiter amplifier 32, instead of the conventionalmeans of an AGC amplifier and AD converter, the circuit scale becomessmaller, and as a result, the communication apparatus M of the presentembodiment has less cost and can reduce power consumption.

According to the communication apparatus M of the present embodiment,the above mentioned communication apparatus based on the low-speed DLCtransmission method is implemented at low coast and low powerconsumption.

Although the present description discloses various aspects of thetechniques, as mentioned above, major techniques thereof will besummarized.

A delay detector circuit according an aspect is a delay detector circuitthat performs a part of decoding processing for decoding datatransmitted by a transmitter apparatus based on a received wave,comprising: a delay correlation operation unit that performs a delaycorrelation operation on the received wave; an acquisition unit thatdetects whether the received wave is a communication signal transmittedby the transmitter apparatus based on the output of the delaycorrelation operation unit; and an output unit that outputs the outputof the delay correlation operation unit to a decoding unit that decodesthe data based on the output of the delay correlation operation unit.

In a delay detector circuit having this configuration, the delaydetection is performed by the delay correction operation unit performingthe delay correlation operation on the received wave and the acquisitionunit detecting whether the received wave is a communication signaltransmitted by the transmitter apparatus based on the output of thedelay correlation operation unit. The result of the delay correlationoperation generated in the middle of the delay detection processing isoutputted to the decoding unit via the output unit. Therefore, comparedwith a case of dividing the received wave into two, performing the delaydetection using one of the received waves and performing decoding usingthe other received wave, the delay detector circuit having thisconfiguration, which uses a part of the delay detector circuit fordecoding processing, has low cost and can reduce power consumption.

The output unit here may be a terminal that outputs the output of thedelay correlation operation unit, for example, or may be wiring thatconnects the delay correlation operation unit and the decoding unit(e.g. including lead line, wiring pattern on a board, and wiring patternon an integrated circuit).

According to another aspect, in the above-described delay detectorcircuit, the acquisition unit comprises: a pattern candidate storageunit that stores, in advance, a plurality of candidates for a shape ofone symbol as pattern candidates; a shape generation unit that generatesa shape of one symbol based on the output of the delay correlationoperation unit; a comparison unit that compares the shape of one symbolgenerated by the shape generation unit and each of the plurality ofpattern candidates; and a conformance determination unit that determinesthat the received wave is a communication signal transmitted by thetransmitter apparatus when the shape of one symbol generated by theshape generation unit and any of the plurality of pattern candidatesmatch for a plurality of times as a result of the comparison by thecomparison unit.

In the delay detector circuit having this configuration, a plurality ofcandidates of a shape of one symbol are provided in advance. Thereforeit is easier to determine that the received wave is a communicationsignal transmitted by the transmitter apparatus, and the delay detectorcircuit having this configuration can acquire the received wave withcertainty. On the other hand, this delay detector circuit regards thatthe received wave is a communication signal transmitted by thetransmitter apparatus (synchronization acquisition) if a shape of onesymbol generated by the shape generation unit and any one of theplurality of pattern candidates match a plurality of times. Thereforethe delay detector circuit having this configuration can determine thatthe received wave is a communication signal transmitted by thetransmitter apparatus, and can accurately perform delay detection.

According to another aspect, in the above-described delay detectorcircuit, the shape generation unit comprises: a square operation unitthat squares the output of the delay correlation operation unit; athreshold comparison unit that binarizes the output of the squareoperation unit by comparing the output of the square operation unit anda predetermined threshold; and a register unit that stores the output ofthe threshold comparison unit for one symbol.

According to this configuration, the shape generation unit isappropriately implemented, and the delay detector circuit isappropriately implemented.

According to another aspect, in the above-described delay detectorcircuit, the shape of one symbol is represented by a plurality of bits,the pattern candidate is a predetermined bit pattern formed byspecifying a value of each bit in advance, the plurality of patterncandidates are mutually different bit patterns, and in at least one ofthe plurality of pattern candidates, at least one of the bits has anarbitrary value.

According to the delay detector circuit having this configuration, in atleast one of the plurality of pattern candidates, at least one of thebits has an arbitrary value. Therefore even if the shape of the symbolbecomes different from the waveform transmitted by the transmitterapparatus during transmission, the received wave can be regarded as thecommunication signal transmitted by the transmitter apparatus, and thedelay detector circuit having this configuration can acquire thereceived wave with more certainty.

According to another aspect, in the above-described delay detectorcircuit further comprises a tracking unit that adjusts a time intervalcorresponding to a time length of one symbol when a predeterminedprocessing is performed with the time interval, so that decoding can beperformed in a center time position of one symbol.

The delay detector circuit according to this configuration further hasthe tracking unit, therefore the shift between the clock interval of thetransmitter apparatus and the clock interval of the receiver apparatusis corrected, and delay detection can be performed with more certainty.

According to another aspect, in the above-described delay detectorcircuit, the tracking unit comprises: a second register unit that storesa square result generated by squaring the output of the delaycorrelation operation unit for one symbol; and an interval adjustmentunit that compares a value at a center time position, which is locatedapproximately at the center of the square result for one symbol storedin the second register unit, a value at a preceding time position thatprecedes the center time position, and a value at a subsequent timeposition that is subsequent to the center time position, and adjusts thetime interval according to the comparison result.

According to this configuration, the tracking unit is appropriatelyimplemented and the delay detector circuit is appropriately implemented.

According to another aspect, the above-described delay detector circuitfurther comprises a decoding unit that decodes the data based on theoutput of the delay correlation operation unit.

The delay detector circuit having this configuration further comprisesthe decoding unit, hence data can be decoded based on the received wave.

According to another aspect, in the above-described delay detectorcircuit, the decoding unit comprises: a third register that stores theoutput of the delay correlation operation unit for one symbol; and adata decoding unit that decodes data based on the value at a centerposition that is located approximately at the center of the thirdregister.

According to this configuration, the decoding unit is appropriatelyimplemented and the delay detector circuit is appropriately implemented.

According to another aspect, in the above-described delay detectorcircuit, the decoding unit comprises: a third register that stores theoutput of the delay correlation operation unit for one symbol; and asecond data decoding unit that decodes data based on a value at a centerposition that is located approximately at the center of the thirdregister, a value at a preceding time position that precedes the centerposition, and a value at a subsequent time position that is subsequentto the center position.

According to this configuration, decoding is performed considering notonly the value at the center position located approximately at thecenter of the third register, but also a value at the preceding positionof the center position and the value at the subsequent position of thecenter position, such as each value of a predetermined number of bits(one or a plurality of bits) located immediately before and immediatelyafter the center position, hence a delay detector circuit having thisconfiguration can decode data more accurately.

According to another aspect, in the above-described delay detectorcircuit, the communication signal is formed in a frame configurationconstituted by a preamble portion and a payload portion, and when theacquisition unit determines that a received wave is a communicationsignal transmitted by the transmitter apparatus based on the output ofthe delay correlation operation unit, the acquisition unit furtherdetects the fulfillment of the preamble portion based on the output ofthe decoding unit.

The delay detector circuit having this configuration can establishsynchronization with the transmission signal by detecting the end of thepreamble portion based on the output of the decoding unit.

A receiver apparatus according to another aspect comprises: a couplingunit that extracts a received wave based on a communication signal froma transmission line; a receive unit that decodes the communicationsignal data, based on the received wave extracted by the coupling unit;and a power receiving unit that generates drive power driving thereceive unit in use of power flowing over the transmission line, whereinthe receive unit comprises any one of the above mentioned delay detectorcircuits.

The receiver apparatus having this configuration, that has any one ofthe above mentioned delay detector circuits, has low cost and can reducepower consumption.

This application is based on Japanese Patent Application No. 2010-022670filed on Feb. 4, 2010, and content thereof is included in the presentapplication.

Although the present invention has been described appropriately andsufficiently through the embodiments, with reference to the drawings,those skilled in the art can easily change and/or modify the abovementioned embodiments. Therefore it should be interpreted that thechanges or modifications made by those skilled in the art are includedin the scope of the Claims, unless the scope of the Claims are departedfrom.

INDUSTRIAL APPLICABILITY

According to the present invention, a delay detector circuit and areceiver apparatus that uses the delay detector circuit can be provided.

1. A delay detection circuit that performs a part of decoding processingfor decoding data transmitted by a transmitter apparatus based on areceived wave, comprising: a delay correlation operation unit thatperforms a delay correlation operation on the received wave; anacquisition unit that detects whether the received wave is acommunication signal transmitted by the transmitter apparatus based onan output of the delay correlation operation unit; and an output unitthat outputs the output of the delay correlation operation unit to adecoding unit that decodes the data based on the output of the delaycorrelation operation unit.
 2. The delay detector circuit according toclaim 1, wherein the acquisition unit comprises: a pattern candidatestorage unit that stores, in advance, a plurality of candidates for ashape of one symbol as pattern candidates; a shape generation unit thatgenerates a shape of one symbol based on the output of the delaycorrelation operation unit; a comparison unit that compares the shape ofone symbol generated by the shape generation unit and each of theplurality of pattern candidates; and a conformance determination unitthat determines that the received wave is a communication signaltransmitted by the transmitter apparatus when the shape of one symbolgenerated by the shape generation unit and any of the plurality ofpattern candidates match for a plurality of times as a result of thecomparison by the comparison unit.
 3. The delay detector circuitaccording to claim 2, wherein the shape generation unit comprises: asquare operation unit that squares the output of the delay correlationoperation unit; a threshold comparison unit that binarizes the output ofthe square operation unit by comparing the output of the squareoperation unit and a predetermined threshold; and a register unit thatstores the output of the threshold comparison unit for one symbol. 4.The delay detector circuit according to claim 2, wherein the shape ofone symbol is represented by a plurality of bits, the pattern candidateis a predetermined bit pattern formed by specifying a value of each bitin advance, the plurality of pattern candidates are mutually differentbit patterns, and in at least one of the plurality of patterncandidates, at least one of the bits has an arbitrary value.
 5. Thedelay detector circuit according to claim 1, further comprising: atracking unit that adjusts a time interval corresponding to a timelength of one symbol when a predetermined processing is performed withthe time interval, so that decoding can be performed at a center timeposition of one symbol.
 6. The delay detector circuit according to claim5, wherein the tracking unit comprises: a second register unit thatstores a square result generated by squaring the output of the delaycorrelation operation unit for one symbol; and an interval adjustmentunit that compares a value at a center time position, which is locatedapproximately at the center of the square result for one symbol storedin the second register unit, a value at a preceding time position thatprecedes the center time position, and a value at a subsequent timeposition that is subsequent to the center time position, and adjusts thetime interval according to the comparison result.
 7. The delay detectorcircuit according to claim 1, further comprises: a decoding unit thatdecodes the data based on the output of the delay correlation operationunit.
 8. The delay detector circuit according to claim 7, wherein thedecoding unit comprises: a third register that stores the output of thedelay correlation operation unit for one symbol; and a data decodingunit that decodes data based on the value at a center position that islocated approximately at the center of the third register.
 9. The delaydetector circuit according to claim 7, wherein the decoding unitcomprises: a third register that stores the output of the delaycorrelation operation unit for one symbol; and a second data decodingunit that decodes data based on a value at a center position that islocated approximately at the center of the third register, a value at apreceding time position that precedes the center position, and a valueat a subsequent time position that is subsequent to the center position.10. The delay detector circuit according to claim 7, wherein thecommunication signal is formed in a frame configuration constituted by apreamble portion and a payload portion, and when the acquisition unitdetermines that a received wave is a communication signal transmitted bythe transmitter apparatus based on the output of the delay correlationoperation unit, the acquisition unit further detects the fulfillment ofthe preamble portion based on the output of the decoding unit.
 11. Areceiver apparatus, comprising: a coupling unit that extracts a receivedwave based on a communication signal from a transmission line; a receiveunit that decodes the communication signal data, based on the receivedwave extracted by the coupling unit; and a power receiving unit thatgenerates drive power driving the receive unit in use of power flowingover the transmission line, wherein the receive unit comprises the delaydetector circuit according to claim 1.